NMR structure of the Aquifex aeolicus tmRNA pseudoknot PK1: new insights into the recoding event of the ribosomal trans-translation

The transfer-messenger RNA (tmRNA) pseudoknot PK1 is essential for bacterial trans-translation, a ribosomal rescue mechanism. We report the solution structure of PK1 from Aquifex aeolicus, which despite an unprecedented small number of nucleotides and thus an unprecented compact size, displays a very high thermal stability. Several unusual structural features account for these properties and indicate that PK1 belongs to the class of ribosomal frameshift pseudoknots. This suggests a similarity between the mechanism of programmed ribosomal frameshifting and trans-translation

The tRNA-like domains of E coli and A.aeolicus transfer-messenger RNA: structural and functional studies.

International audienceTransfer-messenger RNA (tmRNA, 10Sa RNA or ssrA) acts to rescue stalled bacterial ribosomes while encoding a peptide tag added trans-translationally to the nascent peptide, targeting it for proteolysis. The understanding at molecular level of this ubiquitous quality control system in eubacteria requires structural information. Here, we describe the purification and structural analysis of a functional fragment of both Aquifex aeolicus and Escherichia coli tmRNA, recapitulating their tRNA-like domain, which were expressed in vivo from synthetic genes. Both recombinant RNA are correctly processed at both 5' and 3' ends and are produced in quantities suitable for structural analysis by NMR and/or X-ray crystallography. The sequence and solution structure of the tRNA-like domains were analysed by various methods including structural mapping with chemical and enzymatic probes and 2D NMR spectroscopy. The minimalist RNAs contain two post-transcriptional base modifications, 5-methyluridine and pseudouridine, as the full-length tmRNA. Both RNAs fold into three stems, a D-analogue, a T-loop and a GAAA tetra-loop. 2D NMR analysis of the imino proton resonances of both RNAs allowed the assignment of the three stems and of a number of tertiary interactions. It shows the existence of interactions between the TPsiC-loop and the D-analogue, exhibiting a number of similarities and also differences with the canonical tRNA fold, indicating that RNA tertiary interactions can be modulated according to the sequence and secondary structure contexts. Furthermore, the E.coli minimalist RNA is aminoacylatable with alanine with a catalytic efficiency an order of magnitude higher than that for full-length tmRNA

Capsicumicine, a new bioinspired peptide from red peppers prevents staphylococcal biofilm in vitro and in vivo via a matrix anti-assembly mechanism of action

Staphylococci are pathogenic biofilm-forming bacteria and a source of multidrug resistance and/or tolerance causing a broad spectrum of infections. These bacteria are enclosed in a matrix that allows them to colonize medical devices, such as catheters and tissues, and that protects against antibiotics and immune systems. Advances in antibiofilm strategies for targeting this matrix are therefore extremely relevant. Here, we describe the development of the Capsicum pepper bioinspired peptide “capsicumicine.” By using microbiological, microscopic, and nuclear magnetic resonance (NMR) approaches, we demonstrate that capsicumicine strongly prevents methicillin-resistant Staphylococcus epidermidis biofilm via an extracellular “matrix anti-assembly” mechanism of action. The results were confirmed in vivo in a translational preclinical model that mimics medical device-related infection. Since capsicumicine is not cytotoxic, it is a promising candidate for complementary treatment of infectious diseases

NMR structure of a kissing complex formed between the TAR RNA element of HIV-1 and a LNA-modified aptamer

The trans-activating responsive (TAR) RNA element located in the 5′ untranslated region of the HIV-1 genome is a 57-nt imperfect stem-loop essential for the viral replication. TAR regulates transcription by interacting with both viral and cellular proteins. RNA hairpin aptamers specific for TAR were previously identified by in vitro selection [Ducongé,F. and Toulmé,J.J. (1999) In vitro selection identifies key determinants for loop-loop interactions: RNA aptamers selective for the TAR RNA element of HIV-1. RNA, 5, 1605–1614]. These aptamers display a 5′-GUCCCAGA-3′ consensus apical loop, partially complementary to the TAR one, leading to the formation of a TAR–aptamer kissing complex. The conserved GA combination (underlined in the consensus sequence) has been shown to be crucial for the formation of a highly stable complex. To improve the nuclease resistance of the aptamer and to increase its affinity for TAR, locked nucleic acid (LNA) nucleotides were introduced in the aptamer apical loop. LNA are nucleic acids analogues that contain a 2′-O,4′-C methylene linkage and that raise the thermostablity of duplexes. We solved the NMR solution structure of the TAR–LNA-modified aptamer kissing complex. Structural analysis revealed the formation of a non-canonical G•A pair leading to increased stacking at the stem-loop junction. Our data also showed that the introduction of LNA residues provides an enhanced stability while maintaining a normal Watson–Crick base pairing with a loop–loop conformation close to an A-type

The PNA–DNA hybrid I-motif: implications for sugar–sugar contacts in i-motif tetramerization

We have created a hybrid i-motif composed of two DNA and two peptide nucleic acid (PNA) strands from an equimolar mixture of a C-rich DNA and analogous PNA sequence. Nano-electrospray ionization mass spectrometry confirmed the formation of a tetrameric species, composed of PNA–DNA heteroduplexes. Thermal denaturation and CD experiments revealed that the structure was held together by C-H(+)-C base pairs. High resolution NMR spectroscopy confirmed that PNA and DNA form a unique complex comprising five C-H(+)-C base pairs per heteroduplex. The imino protons are protected from D(2)O exchange suggesting intercalation of the heteroduplexes as seen in DNA(4) i-motifs. FRET established the relative DNA and PNA strand polarities in the hybrid. The DNA strands were arranged antiparallel with respect to one another. The same topology was observed for PNA strands. Fluorescence quenching revealed that both PNA–DNA parallel heteroduplexes are intercalated, such that both DNA strands occupy one of the narrow grooves. H1′–H1′ NOEs show that both heteroduplexes are fully intercalated and that both DNA strands are disposed towards a narrow groove, invoking sugar–sugar interactions as seen in DNA(4) i-motifs. The hybrid i-motif shows enhanced thermal stability, intermediate pH dependence and forms at relatively low concentrations making it an ideal nanoscale structural element for pH-based molecular switches. It also serves as a good model system to assess the contribution of sugar–sugar contacts in i-motif tetramerization

Hairpin structures formed by alpha satellite DNA of human centromeres are cleaved by human topoisomerase IIα

Although centromere function has been conserved through evolution, apparently no interspecies consensus DNA sequence exists. Instead, centromere DNA may be interconnected through the formation of certain DNA structures creating topological binding sites for centromeric proteins. DNA topoisomerase II is a protein, which is located at centromeres, and enzymatic topoisomerase II activity correlates with centromere activity in human cells. It is therefore possible that topoisomerase II recognizes and interacts with the alpha satellite DNA of human centromeres through an interaction with potential DNA structures formed solely at active centromeres. In the present study, human topoisomerase IIα-mediated cleavage at centromeric DNA sequences was examined in vitro. The investigation has revealed that the enzyme recognizes and cleaves a specific hairpin structure formed by alpha satellite DNA. The topoisomerase introduces a single-stranded break at the hairpin loop in a reaction, where DNA ligation is partly uncoupled from the cleavage reaction. A mutational analysis has revealed, which features of the hairpin are required for topoisomerease IIα-mediated cleavage. Based on this a model is discussed, where topoisomerase II interacts with two hairpins as a mediator of centromere cohesion

Structure of a C-rich strand fragment of the human centromeric satellite III: a pH-dependent intercalation topology

International audienceRepetitive DNA sequences may adopt unusual pairing arrangements. At acid to neutral pH, cytidine-rich DNA oligodeoxynucleotides can form the i-motif structure in which two parallel-stranded duplexes with C·C+ pairs are intercalated head-to-tail. The i-motif may be formed by multimeric associations or by intra-molecular folding, depending on the number of cytidine tracts, the nucleotide sequences between them, and the experimental conditions.We have found that a natural fragment of the human centromeric satellite III, d(CCATTCCATTCCTTTCC), can form two monomeric i-motif structures that differ in their intercalation topology and that are favored at pH values higher (the η-form) and lower (the λ-form) than 4.6. The change in intercalation may be related to adenine protonation in the loops.We studied the uridine derivative methylated on the first cytidine base, d(5mCCATTCCAUTCCUTTCC), whose proton spectrum is better resolved. The intercalation topologies are (C7·C17)/(5mC1·C11)/(C6·C16)/(C2·C12) for form λ and (5mC1·C11)/(C7·C17)/(C2·C12)/(C6·C16) for form η. We have solved the structure of the η-form, and we present a model for the λ-form. The switch from η to λ involves disruption of the i-motif. In both forms, the central AUT linker crosses the wide groove, and the first and the third linkers loop across the minor grooves. The i-motif core is extended in the η-form by the inter-loop reverse Watson-Crick A3·U13 pair, whose dissociation constant is around 10−2 at 0 °C, and in the λ-form by the interloop T5·T15 pair.In contrast, d(5mCCATTCCTTACCTTTCC) folds into a pH-independent structure that has the same intercalation topology as the λ-form. The i-motif core is extended below by the interloop T5·T15 pair and closed on top by the T8·A10 pair.Thus, the C-rich strand of the human satellite III tandem repeats, like the G-rich strand, can fold into various compact structures. The relevance of these features to centromeric function remains unknown

Self-organisation of an oligodeoxynucleotide containing the G- and C-rich stretches of the direct repeats of the human mitochondrial DNA.

Stretches of cytosines and guanosines have been shown in vitro to adopt non-canonical structures known as i-motifs and G-quartets, respectively. When combined, such sequences are expected to either retain their structure or form duplexes or triple helices. All these structures may occur in vivo whenever the sequence criteria are met. Such stretches are present in the circular genome of human mitochondria, as two 10 nucleotide-long perfect tandem direct repeats (DR1 and DR2). The DR1 and DR2 repeats are G-rich on the heavy strand and C-rich on the light strand. Previous results suggested that during replication, transient formation of a parallel GGC triple helix between the neo-synthesised G-rich DR1 and the double-stranded homologous DR2 could be involved in a rearrangement process leading to genome instability. In order to get structural insights into the interaction between the two repeats, we have studied by nuclear magnetic resonance (NMR) the assembly properties of a 24-mer oligodeoxyribonucleotide in which the C- and G-rich segments of the DRs are covalently tethered by a TTTT linker. We show here that this 24-mer self-associates into a triplex-containing symmetrical tetramer. The core of the structure is composed of anti-parallel Watson-Crick (WC) base pairs. Two additional strands are hydrogen-bonded to the Hoogsteen side of the Gs, thus forming CGC(+) triple helices, with G-rich ends folding into G-quartets. These results suggest that such structures could occur when the two DRs are put to close proximity in a biological context

The RNA i-motif

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Structure, stabilité et interactions de l'ARNtm avant liaison au ribosome

Résumé en français confidentielRésumé en anglais confidentielPARIS5-Bibliotheque electronique (751069902) / SudocPARIS-BIUM-Bib. électronique (751069903) / SudocSudocFranceF